The present disclosure discloses a machine and a method for peeling skin from un-peeled objects that mainly includes at least one controller, an object: handling unit, an agitating: and heating unit and a peeling and separating unit. The agitating and heating unit includes an agitator and a heater. The agitator receives un-peeled objects and hot abrasive particles. During agitation, un-peeled objects and hot abrasive particles tumble with each other thereby loosing bond between skin and objects and provide objects with loosely bonded skin. The heater heats the abrasive particles and then permits, flow within the agitator by use of abrasive conveyor. Objects with loosely bonded skin are then provided in the peeling and separation unit for peeling and separating skin from un-peeled objects and provide peeled objects in a controlled manner.

A modular nut cleaning plant comprises a nut sizer and a stick remover mounted to the nut sizer. A vacuum unit is mounted to the stick remover. A nut product stream will pass on the stick remover through the vacuum unit which will vacuum light debris from the nut product stream. The nut product stream moves on a chain on the stick remover. Large debris and sticks that do not fall through openings in the chain will pass into a debris conveyor. Nuts and debris that fall through the openings in the chain will be delivered to the nut sizer. The nut sizer will rotate and tumble nuts and debris in the nut product stream. Nuts of an undesirable size and debris will pass into a debris conveyor. Nuts of a desired size will pass through the nut sizer into a chute or other conveyance to be delivered to further nut processing apparatus.

A modular nut cleaning plant comprises a nut sizer and a stick remover mounted to the nut sizer. A vacuum unit is mounted to the stick remover. A nut product stream will pass on the stick remover through the vacuum unit which will vacuum light debris from the nut product stream. The nut product stream moves on a chain on the stick remover. Large debris and sticks that do not fall through openings in the chain will pass into a debris conveyor. Nuts and debris that fall through the openings in the chain will be delivered to the nut sizer. The nut sizer will rotate and tumble nuts and debris in the nut product stream. Nuts of an undesirable size and debris will pass into a debris conveyor. Nuts of a desired size will pass through the nut sizer into a chute or other conveyance to be delivered to further nut processing apparatus.

Methods and systems for producing improved hemp seed products, such as proteins and oils are provided.

Methods and systems for producing improved hemp seed products, such as proteins and oils are provided.

The present disclosure provides a peanut whole-process production line and a method. The peanut whole-process production line includes a peanut cleaning system, a shell breaking system, a skin removing system, a peanut kernel classification system, an ultra-fine pulverization system and a classification packaging system; a first procedure is cleaning and impurity removal of peanuts, breaking of peanut shells is performed after the cleaning and impurity removal of peanuts, removal of peanut kernel skins and ultra-fine pulverization of the peanut shells are respectively performed after the breaking of peanut shells, classification of peanut kernels is performed after the removal of peanut kernel skins, and classification packaging of ultra-fine peanut shell powder is performed after the ultra-fine pulverization of the peanut shells; whole-process processing of peanuts is completed by using the peanut whole-process production line, and peanut resources are fully utilized.

A method of separating a shell from a seed may involve introducing a feed stream containing shells of a fruit intermixed with seeds of the fruit into a separation column at a feed stream location. The method may also involve introducing a first volume of a separation liquid into the separation column at a first liquid addition location located below the feed stream location and a second volume of the separation liquid into the separation column at a second liquid addition location located above feed stream location. The separation liquid may flow upwardly in the separation column at a rate effective to cause the seeds of the fruit to flow upwardly with the separation liquid toward a seed outlet of the separation column while the shells of the fruit flow downwardly against the upwardly flowing separation liquid toward a shell outlet of the separation column.

A nut cracking apparatus has a frame with a rotatable turret mounted thereto. A plurality of nut cracking units in the rotatable turret comprise pistons movable from a retracted position to an extended position and crack dies aligned with the piston. Air is communicated through feed air passages in the rotatable turret to urge the pistons from a retracted to an extended position.

A nut cracking apparatus has a frame with a rotatable turret mounted thereto. A plurality of nut cracking units in the rotatable turret comprise pistons movable from a retracted position to an extended position and crack dies aligned with the piston. Air is communicated through feed air passages in the rotatable turret to urge the pistons from a retracted to an extended position.

A machine for the integral processing of hard or soft shelled nuts herein proposed comprises a feeding hopper and at least one receptacle having a first end for connection to said hopper and a second opposite end, where said receptacle is located in a horizontal position according to the longitudinal direction of the machine and comprises therein a central shaft located according to the longitudinal direction thereof and connected at one end to a rotating element, where said central shaft has finger-like elements projecting radially outwards from various longitudinal positions thereof.